An apparatus for in-situ calibration of a photoacoustic sensor is provided. The apparatus includes a calibration unit that includes at least one processor configured to calculate calibration information. A light emitter of the photoacoustic sensor is configured to emit an electromagnetic spectrum and the photoacoustic sensor is configured to provide at least two measurement signals based on at least two electromagnetic spectra. The calibration unit is configured to compare the at least two measurement signals to obtain the calibration information and apply the calibration information to the photoacoustic sensor to perform the in-situ calibration.
|
9. A method for in-situ calibration of a photoacoustic sensor, the method comprising:
calculating a calibration information, wherein an ir emitter of the photoacoustic sensor is configured to emit a first electromagnetic spectrum that is sensitive to a gas and a second electromagnetic spectrum that is not sensitive to the gas based on an electric signal, wherein the photoacoustic sensor is configured to provide at least two measurement signals based on the first and the second electromagnetic spectrum passing through the gas; and
comparing the at least two measurement signals to obtain calibration information; and
applying the calibration information to the photoacoustic sensor to perform the in-situ calibration.
1. An apparatus for in-situ calibration of a photoacoustic sensor, the apparatus comprising:
a calibration unit comprising at least one processor, configured to calculate calibration information, wherein a light emitter of the photoacoustic sensor is configured to emit a first electromagnetic spectrum that is sensitive to a gas and a second electromagnetic spectrum that is not sensitive to the gas, wherein the photoacoustic sensor is configured to provide at least two measurement signals based on the first and the second electromagnetic spectrum passing through the gas,
wherein the calibration unit is configured to compare the at least two measurement signals to obtain the calibration information, and
wherein the calibration unit is configured to apply the calibration information to the photoacoustic sensor to perform the in-situ calibration.
19. A method for in-situ calibration of a photoacoustic sensor, the method comprising:
calculating a calibration information, wherein an ir emitter of the photoacoustic sensor is configured to emit an electromagnetic spectrum based on an electric signal, wherein the photoacoustic sensor is configured to provide at least two measurement signals based on at least two electromagnetic spectra; and
comparing the at least two measurement signals to obtain calibration information;
calculating a current ratio of a first one of the at least two measurement signals and a second one of the at least two measurement signals;
comparing the current ratio to a target ratio;
applying the calibration information to the photoacoustic sensor to perform the in-situ calibration; and
adjusting an electric power of the ir emitter such that an absolute difference of the current ratio to the target ratio is reduced.
17. An apparatus for in-situ calibration of a photoacoustic sensor, the apparatus comprising:
a calibration unit comprising at least one processor, configured to calculate calibration information, wherein a light emitter of the photoacoustic sensor is configured to emit a plurality of electromagnetic spectrum, wherein the photoacoustic sensor is configured to provide at least two measurement signals based on at least two electromagnetic spectra,
wherein the calibration unit is configured to compare the at least two measurement signals to obtain the calibration information,
wherein the calibration unit is configured to apply the calibration information to the photoacoustic sensor to perform the in-situ calibration,
wherein the calibration unit is configured to calculate a current ratio of a first one of the at least two measurement signals and a second one of the at least two measurement signals,
wherein the calibration unit is further configured to compare the current ratio to a target ratio, and
wherein the calibration unit is configured to adjust an electric power of the light emitter such that an absolute difference of the current ratio to the target ratio is reduced.
2. The apparatus according to
3. The apparatus according to
wherein the light emitter is configured to emit an electromagnetic spectrum based on the electric signal, and
wherein the calibration unit is further configured to adjust the electric signal at the light emitter based on the calibration information to perform the in-situ calibration.
4. The apparatus according to
a processing unit, comprising as least one further processor, configured to calibrate a determination of a gas concentration in the photoacoustic sensor using the calibration information to perform the in-situ calibration,
wherein the determination of the gas concentration is based on a further measurement signal of the photoacoustic sensor.
5. The apparatus according to
a processing unit, comprising as least one further processor, configured to process an output signal of the photoacoustic sensor based on the calibration information to obtain an adjusted output signal of the photoacoustic sensor.
6. The apparatus according to
the calibration unit is configured to calculate a current ratio of a first one of the at least two measurement signals and a second one of the at least two measurement signals,
the calibration unit is further configured to compare the current ratio to a target ratio, and
the calibration unit is configured to adjust an electric power of the light emitter such that an absolute difference of the current ratio to the target ratio is reduced.
7. The apparatus according to
8. The apparatus according to
10. The method of
11. The method of
controlling an electric signal at the ir emitter;
emitting an electromagnetic spectrum from the ir emitter based on the electric signal; and
adjusting the electric signal at the ir emitter based on the calibration information to perform the in-situ calibration.
12. The method of
calibrating a determination of a gas concentration in the photoacoustic sensor using the calibration information to perform the in-situ calibration,
wherein the determination of the gas concentration is based on a further measurement signal of the photoacoustic sensor.
13. The method of
processing an output signal of the photoacoustic sensor based on the calibration information to obtain an adjusted output signal of the photoacoustic sensor.
14. The method of
calculating a current ratio of a first one of the at least two measurement signals and a second one of the at least two measurement signals;
comparing the current ratio to a target ratio; and
adjusting an electric power of the ir emitter such that an absolute difference of the current ratio to the target ratio is reduced.
15. The method of
16. The method of
18. The apparatus according to
20. The method of
|
This application is a divisional of U.S. patent application Ser. No. 15/258,646, filed Sep. 7, 2016, which, claims the benefit of German Patent Application No. 10 2015 217 098.5 filed Sep. 7, 2015, which are incorporated by reference as if fully set forth.
The present disclosure relates to an apparatus and a method for in-situ calibration of a photoacoustic sensor based on calibration information acquired during operation of the photoacoustic sensor.
Gas sensors suffer from multiple calibration procedures and a fast replacement of the gas sensors after having a comparably short life cycle. Typical calibration procedures adjust a zero line of the sensor based on a lowest measured value within a predetermined period, such as for example a couple of days. However, it is only applicable for sensors having periods of time, where a gas compound that shall be measured is absent and is therefore limited in its usage. Furthermore, its calibration method is not very precise.
A different calibration procedure may use a reference sensor being in use only for measuring a calibration value and therefore suffering from less degradation than the main sensor which shall be calibrated. However, this is expensive, elaborate, and the whole (photoacoustic) sensor becomes larger since the reference sensor needs to be included.
Therefore, there is a need for an improved approach.
The in-situ calibration of a photoacoustic sensor may be conducted by adjusting an IR emitter based on the calibration information or by performing a corrected processing of the output signal of the IR emitter (or a signal derived from the output signal). Further embodiments show a microelectromechanical system comprising the apparatus. Further embodiments relate to a (in use) calibration of a photoacoustic sensor (PAS) module.
Embodiments are based on the finding that an in-situ or in use calibration of a photoacoustic sensor may be performed to overcome the aforementioned limitations. Therefore, gas sensors may have a high and steady precision over their whole life cycle. Upcoming, multiple embodiments for in-situ calibration, e.g. related to calibrate the photoacoustic sensor with adjusting an infrared (IR) emitter, are shown.
To be more specific, embodiments are based on the finding that an in-situ or in use calibration of a photoacoustic sensor may be performed based on calibration information which may be derived from a physical parameter or characteristic of the photoacoustic sensor or, for example, of the IR emitter of the photoacoustic sensor, and which are achieved or detected during operation of the photoacoustic sensor. The in-situ calibration of a photoacoustic sensor may be conducted by adjusting an IR emitter based on the calibration information, e.g. by adjusting a control signal fed to the IR emitter and/or by correcting the output signal of the IR emitter (or a signal derived from the output signal).
Moreover, the in-situ calibration of a photoacoustic sensor may be conducted during processing or evaluating the output signal of the IR emitter (or a signal derived from the output signal), wherein the detected calibration information is incorporated into the processing or evaluating of the output signal of the IR emitter (or a signal derived from the output signal). As a result, a corrected (e.g. calibrated) processing or evaluating of the output signal of the IR emitter (or a signal derived from the output signal) can be achieved.
Embodiments relate to an apparatus for in-situ calibration of a photoacoustic sensor e.g. achieved with adjusting an IR emitter. The apparatus comprises a measurement device and a calibration unit. The measurement device is configured to detect or to measure a current electric signal (instantaneous signal) at or through the IR emitter of the photoacoustic sensor, wherein the calibration unit may compare the current electric signal at the IR emitter with a comparison value for the electric signal to achieve a comparison result forming a calibration information. When performing the in-situ calibration, the calibration information is applicable to the photoacoustic sensor for adjusting the IR emitter and/or is applicable to an output signal of the photoacoustic sensor for correcting the output signal. According to embodiments, the calibration unit may adjust the current electric signal based on the comparison result (or the calibration information) to obtain a target electric signal at the IR emitter from the in-situ calibration.
According to further embodiments, the apparatus may comprise an optional processing unit to process the output signal of the photoacoustic sensor based on the calibration information to obtain an adjusted output signal of the photoacoustic sensor. The output signal of the photoacoustic sensor may be a response of an acoustic sensor element such as a microphone of the photoacoustic sensor to the IR radiation of the IR emitter or a gas concentration of a gas component of the measurement gas or a composition of the measurement gas. More specifically, the acoustic sensor element responds to the photoacoustic signal of the measurement gas which is stimulated by the IR radiation or the light emitted by the IR/light emitter. However, the calibration information may be provided to the IR emitter or to the processing unit or to both, the IR emitter and the processing unit. In other words, a direct adjustment of the IR emitter may perform an adjustment of the IR radiation of the IR emitter, wherein an indirect adjustment may calculate a calibration value based on e.g. a deviation of the (current) IR radiation (measure) to a calibrated IR radiation (measure), e.g. using a lookup table, to adjust the output signal of the photoacoustic sensor.
In other words, the apparatus may detect or measure a current voltage (or instantaneous voltage) at the IR emitter or a current electrical current (or instantaneous electrical current) through the IR emitter, for example to calculate a current electric power (or instantaneous electrical power) at the IR emitter, and to adjust the current electric power to a predetermined value or desired value of the electric power. The predetermined or desired value may be obtained from a lookup table or further matching means, mapping the (current) electric power to a temperature or an emissivity of the IR emitter, wherein the emissivity of the IR emitter may refer to an electromagnetic radiation, such as for example an IR or temperature radiation. In other words, the calibration unit may adjust the current electric power such that a target value of a physical characteristic or physical characteristic of the IR emitter is obtained.
Moreover, embodiments show that the calibration unit is configured to adjust the current electric signal such that a change of resistance of the IR emitter is compensated. A change of resistance of the IR emitter may effect a current voltage at the IR emitter or a current electrical current through the IR emitter and therefore effects a power input to the IR emitter. However, the power input of the IR emitter is directly related to a temperature or an emissivity of the IR emitter, resulting in a shifted wavelength of an electromagnetic radiation of the IR emitter. The resistance of the IR emitter may change for example due to a degradation of the IR emitter.
According to further embodiments, the current electric signal comprises an electric pulse, e.g. pulse signal or pulsed signal. Moreover, the calibration unit is configured to calculate a time constant at the further acoustic sensor from the current (or instantaneous) physical characteristic based on the electric pulse, wherein the time constant indicates an ability of the current physical characteristic to follow the electric pulse. In other words, an AC current behavior or, more specifically, a transient behavior of the IR emitter and the current electric signal may be calculated. This behavior may be for example characterized using a time constant, which may be calculated by analyzing an impulse response or a step (function) response of the IR emitter to the electric pulse. Therefore, the electric pulse may be a sine or cosine pulse or signal, a rectangular function or a (proximity of a) Dirac impulse.
Moreover, the calibration unit may be configured to adjust the electric pulse such that at least one of an edge steepness, an amplitude, or a repetition frequency of the electric pulse is changed. The change of the electric pulse (or a sequence of electric pulses or a pulse(d) signal) may also change the physical characteristic of the IR emitters such that the absolute difference between the current physical characteristic and the target value of the physical characteristic is reduced. In other words, the aforementioned sine or cosine wave or pulse, the rectangular signal or the Dirac pulse may be modified such that an electric power at the IR emitter, a temperature of the IR emitter or an emissivity of the IR emitter is adjusted to their target values. Additionally or alternatively, the electric pulse may be only a measurement signal to obtain a calibration value. Therefore, a property characterizing the amount of calibration that has to be performed on the IR emitter, such that for example the time constant, which may be derived from the electric pulse and a measurement signal used for operating the photoacoustic sensor is adjusted based on the property. In general, the current physical characteristic may be different from the target value of the physical characteristic due to a degradation of the IR emitter and wherein the calibration unit may be configured to adjust the electric pulse or in general, the current electric signal, such that a degradation of the IR emitter is compensated.
Further embodiments relate to an apparatus for in-situ calibration of a photoacoustic sensor e.g. achieved with adjusting an IR emitter. The apparatus comprises a calibration unit and a sensing unit. The calibration unit is configured to control a signal generator such that the signal generator feeds an IR emitter of the photoacoustic sensor with an electric pulse or pulse(d) signal. The sensing unit is configured to detect or measure a current physical characteristic of a surface of the IR emitter, wherein the current physical characteristic of the IR emitter depends on the electric pulse. Moreover, the calibration unit may compare the current physical characteristic of the surface of the IR emitter with the target value of the physical characteristic of the surface of the IR emitter to obtain a calibration signal forming a calibration information. When performing the in-situ calibration, the calibration information (or the calibration signal) is applicable to the signal generator for adjusting the IR emitter and/or is applicable to an output signal of the photoacoustic sensor for correcting the output signal.
Therefore, the calibration unit may adjust the electric pulse of the signal generator based on the calibration signal to perform the in-situ calibration. In other words, a temperature or an emissivity, such as for example the ability to emit electromagnetic radiation, may be determined. Therefore, a temperature sensor may measure a temperature of an environment of the IR emitter, which is for example a temperature of a gas surrounding the IR emitter. This may refer to an indirect measurement of the temperature of the IR emitter.
According to further embodiments, the apparatus comprises a processing unit configured to process an output signal of the photoacoustic sensor based on the calibration information (or calibration signal) to obtain an adjusted output signal of the photoacoustic sensor. The output signal of the photoacoustic sensor may be a response of an acoustic sensor element of the photoacoustic sensor to the IR radiation of the IR emitter or a gas concentration of a gas component of the measurement gas or a composition of the measurement gas. However, the calibration information may be provided to the IR emitter or to the processing unit or to both, the IR emitter and the processing unit. In other words, a direct adjustment of the IR emitter may perform an adjustment of the IR radiation of the IR emitter, wherein an indirect adjustment may calculate a calibration value based on e.g. a deviation of the (current) IR radiation (measure) to a calibrated IR radiation (measure), e.g. using a lookup table, to adjust the output signal of the photoacoustic sensor.
Additionally or alternatively, a contactless measurement of temperature radiation, heat radiation, or IR radiation may be performed using for example an infrared detector. More specifically, the sensing unit may be configured to measure a temperature of the surface of the IR emitter using determining a temperature of an environment of the IR emitter or a sensing unit may measure an infrared radiation of the IR emitter at the surface of the IR emitter.
Embodiments further show that the calibration unit may be configured to calculate a time constant of the photoacoustic sensor from the current physical characteristic based on the current electric pulse, wherein the time constant indicates an ability of the current physical characteristic to follow the electric pulse. Furthermore, the calibration unit may adjust the electric pulse such that at least one of an edge steepness, an amplitude, or a repetition frequency of the electric pulse is changed, wherein the change of the electric pulse changes the physical characteristic of the IR emitter such that the absolute difference between the current physical characteristic and the target value of the physical characteristic is reduced. In general, the current physical characteristic may be different from the target value of the physical characteristic due to a degradation of the IR emitter and wherein the calibration unit may be configured to adjust the electric pulse such that the calibration of the IR emitter is compensated. According to further embodiments, the electric pulse may be used for determining only an amount of degradation of the IR emitter, wherein a value indicating the amount of degradation is used to adjust a measurement signal of the IR emitter to operate the photoacoustic sensor during normal operation.
According to further embodiments, the apparatus may comprise the signal generator, wherein the signal generator may be configured to generate the electric pulse and to feed the IR emitter of the photoacoustic sensor with the electric pulse. It is advantageous, since the signal generator may be easily implemented in the apparatus and furthermore, a phase of the combination of the apparatus and the photoacoustic sensor is reduced, since no external signal generator needs to be used. Additionally or alternatively, a signal generator may be further implemented in the photoacoustic sensor.
According to a further embodiment, the apparatus and the IR emitter of the photoacoustic sensor may be formed on a common semiconductor substrate. Furthermore, the sensing unit may comprise a semiconductor temperature sensing unit formed within the semiconductor substrate. One of an easiest way to implement the temperature sensing unit of the semiconductor may be to use a pn junction, or in general, differently doped areas of the semiconductor substrate to form an area within the semiconductor substrate being sensitive to temperature changes. The semiconductor temperature sensing unit may therefore measure a temperature of the environment of the IR emitter, which is approximately a temperature of a surface of the IR emitter and therefore indicates an ability of the IR emitter to heat the environment when compared to an input power of the IR emitter. Additionally or alternatively, a sensing unit may be an infrared sensor being integrated into the semiconductor substrate. This may be, for example, an infrared diode or a bolometer.
Further embodiments relate to an apparatus for in-situ calibration of a photoacoustic sensor. The apparatus comprises a calibration unit configured to calculate a calibration information. An IR emitter of the photoacoustic sensor may emit an electromagnetic spectrum (e.g. an electromagnetic signal or electromagnetic radiation having an electromagnetic spectrum), wherein the photoacoustic sensor is configured to provide at least two measurement signals based on at least two electromagnetic spectra. Moreover, the calibration unit is configured to compare the at least two measurement signals to obtain the calibration information and to apply the calibration information to the photoacoustic sensor to perform the in-situ calibration. In other words, the photoacoustic sensor may perform two different measurements using two different electromagnetic spectra emitted by the IR emitter, advantageously using the same or at least a similar gas for both measurements, and from comparing the resulting measurement signals to derive information about a current performance of the IR emitter when compared to an originally calibrated performance.
Based on the information of how the current performance of the photoacoustic sensor changed with respect to a calibrated performance of the photoacoustic sensor, for example an input power to the IR emitter may be adjusted to recalibrate the photoacoustic sensor or, an analysis of the measurement signals may be adjusted such that for the same gas concentration a current measurement signal and a measurement signal after calibration of the temperature sensor relate to the same result. This may be achieved by, for example, applying an offset to a lookup table, where a current measurement signal and a corresponding gas concentration are stored.
Additionally or alternatively, both approaches may be applied as, for example, the lookup table comprises a comparably rough resolution and the input power to the IR emitter may be slightly adjusted such that a value within the resolution of the lookup table is met. In other words, the major calibration of the photoacoustic sensor may be done using adjusting adapting, modifying, or regulating a relation between the measurement signal and a related temperature or IR emissivity of the photoacoustic sensor. However, the relation between measurement signal and temperature or IR emissivity may be quantized such as e.g. the lookup table. Therefore, the calibration unit may apply an input signal or power on the IR emitter to slightly adjust the temperature or an IR emissivity of the IR emitter such that the quantization steps are met.
In other words, the calibration unit may be configured to control an electric signal at the IR emitter, wherein the IR emitter is configured to emit an electromagnetic spectrum based on the electric signal, and wherein the calibration unit is further configured to adjust the electric signal at the IR emitter based on the calibration information to perform the in-situ calibration. Furthermore, the calibration unit may be configured to calibrate a determination, identification, or specification of a gas concentration in the photoacoustic sensor using the calibration information to perform the in-situ calibration, wherein the determination, identification, or specification of the gas concentration is based on a further measurement signal of the photoacoustic sensor.
Embodiments of the present invention will be discussed subsequently referring to the enclosed drawings, wherein:
In the following, embodiments of the invention will be described in further detail. Elements shown in the respective figures having the same or a similar functionality will have associated therewith the same reference signs.
According to embodiments, the calibration unit 10 may then adjust the current electric signal based on the comparison result 11 (calibration information) to obtain a target value of the electric signal at the IR emitter to perform the in-situ calibration. Again, the electric signal may be an electric current, a voltage at the IR emitter, or a combination thereof, for example an electric (input) power or a resistance of the IR emitter, or may be derived therefrom.
According to further embodiments, the photoacoustic sensor may optionally comprise a processing unit 15. The processing unit 15 may process the output signal of the photoacoustic sensor based on the calibration information to obtain an adjusted output signal of the photoacoustic sensor 4. The output signal of the photoacoustic sensor may be a response of an acoustic sensor element such as a microphone of the photoacoustic sensor to the photoacoustic signal caused by the IR radiation of the IR emitter to a gas concentration of a gas component of the measurement gas or a composition of the measurement gas. However, the calibration information may be provided to the IR emitter or to the processing unit or to both, the IR emitter and the processing unit. In other words, a direct adjustment of the IR emitter may perform an adjustment of the IR radiation of the IR emitter, wherein an indirect adjustment may calculate a calibration value based on e.g. a deviation of the (current) IR radiation (measure) to a calibrated IR radiation (measure), e.g. using a lookup table, to adjust the output signal of the photoacoustic sensor. Moreover, the processing unit 15 and the calibration unit 10 may be implemented in the same or a common (micro-) processor. In other words, the calibration unit 10 and the processing unit 15 may be implemented or incorporated in (the same) hardware and/or software or at least partially in hardware. Furthermore, the calibration information 11 may be input to the IR emitter 6 or the processing unit 15, dependent on the embodiment.
In other words, a current electric current, voltage, power, or resistance of the IR emitter may be measured using the measurement device 8 and be compared to a target value of the measured electrical property. Furthermore, the power source may be adjusted such that the current physical property or electric signal and the (expected) target value converge. In other words, an absolute difference of (a value of) the current physical property and (a value of) the target value of the physical property may be reduced. A convergence of the current electric signal and a target value of the electric signal is advantageous or may be even necessary to emit a target value or a physical characteristic from the IR emitter. The physical characteristic may be a temperature or an IR radiation of the IR emitter. In other words, the IR emitter itself may be sensor indicating a degradation of the emitter e.g. by a change of resistance. The resistance of the IR emitter suffering from degradation may change differently over the temperature when compared to a calibrated or known temperature range.
Moreover, adjusting the IR emitter or the output signal may refer to a calibration. Therefore, the adjustment may reduce a difference or an error between a current signal having an electromagnetic spectrum and a calibrated value of the electromagnetic spectrum. Accordingly, a difference or an error between a current output signal and a calibrated value of the output signal (as a response to the electromagnetic waves transmitted or emitted by the IR emitter) is reduced. This may refer to a calibrated IR emitter or a calibrated output signal.
Moreover, the calibration unit 10′ is configured to compare the (detected) current physical characteristic of the surface of the IR emitter with a target value of the physical characteristic of the surface of the IR emitter to obtain a calibration signal 11′ forming a calibration information. When performing the in-situ calibration, the calibration information is applicable to the signal generator (12) for adjusting the IR emitter and/or is applicable to an output signal of the photoacoustic sensor for correcting the output signal.
According to embodiments, the calibration unit may adjust the electric pulse 13 of the signal generator 12 based on the calibration signal to perform the in-situ calibration. In other words, the calibration unit determines the physical characteristic at the surface of the IR emitter, wherein the calibration unit compares this value with a target value of the physical characteristic. The target value of the physical characteristic may be a current temperature or IR radiation used for performing a gas concentration measurement. However, the calibration unit may adjust the signal generator, for example a total power or a modulation frequency of an electric signal, such that the target value or the expected value of the physical characteristic is obtained at the surface of the IR emitter.
According to further embodiments, the apparatus 2′ may optionally comprise a processing unit 15 configured to process an output signal of the photoacoustic sensor based on the calibration information to obtain an adjusted output signal of the photoacoustic sensor. The output signal of the photoacoustic sensor may be a response of an acoustic sensor element of the photoacoustic sensor to the IR radiation of the IR emitter or a gas concentration of a gas component of the measurement gas or a composition of the measurement gas. However, the calibration information may be provided to the IR emitter or to the processing unit or to both, the IR emitter and the processing unit. In other words, a direct adjustment of the IR emitter may perform an adjustment of the IR radiation of the IR emitter, wherein an indirect adjustment may calculate a calibration value based on e.g. a deviation of the (current) IR radiation (measure) to a calibrated IR radiation (measure), e.g. using a lookup table, to adjust the output signal of the photoacoustic sensor. Moreover, the processing unit 15 and the calibration unit 10 may be implemented in the same or a common (micro-) processor (or in software) or at least partially in hardware.
The measurement device 8 (e.g. shown in
As already mentioned, power source 12 may be either configured to provide a regular AC or DC power to the IR emitter 6 to perform gas concentration measurements with the photoacoustic sensor during normal operation modes. Moreover, the power source 12 may also be configured to function as a signal generator being able to provide more sophisticated voltages or forms of the electrical current such as, for example, Dirac pulses, rectangular pulses, or step functions. According to further embodiments, the power source or signal generator 12 may be formed in two separate blocks for the signal generation and the power supply for the IR emitter 6.
Furthermore, the current electrical signal 18 may comprise an electric pulse, e.g. a pulse signal or pulsed signal. The electric pulse may be either part of normal operation of the photoacoustic sensor or it may only be applied for calibration purposes during a separate calibration measurement. However, the calibration unit 10 may be configured to calculate a time constant of the photoacoustic sensor from the current physical characteristic based on the electric pulse. The time constant may indicate an ability of the current physical characteristic to follow or track the electric pulse. Moreover, the calibration unit may adjust the electric pulse such that at least one of an edge steepness, an amplitude, or a repetition frequency of the electric pulse is changed and wherein the change of the electric pulse may change the physical characteristic of the IR emitter such that the absolute difference between a current physical characteristic and the target value of the physical characteristic is reduced. However, a difference between the target value of the physical characteristic and a current value of the physical characteristic may be obtained due to a degradation of the IR emitter.
The time constant or a further characteristical property may be, for example, obtained by evaluating a step function, a Dirac impulse, or a rectangular function. The time constant may therefore be a general measure characterizing the emitter performance not only for the currently applied electrical power but for a broad range of operating points such as, for example, all possible operating points of the photoacoustic sensor.
As already described,
This method or operation is especially advantageous for fast photoacoustic sensors based on MEMS components. These sensors may be small and therefore fast, since they comprise a small thermal mass when compared to bigger or larger sensors. However, if the surface of the IR emitter changes, which is for example a change of the material properties, such as for example a corrosion or oxidation of the surface, may result, for example in an offset or a time delay of an IR radiation. Additionally or alternatively, an overall drop of the temperature or an IR radiation of the IR emitter may be also caused.
According to further embodiments, a temperature of the IR emitter may be measured using a temperature sensor such as for example a PT element, a pn-diode, or a bolometer, etc., which may be integrated in the emitter or placed nearby the emitter. Comparing an input power of the IR emitter to an achieved temperature at the IR emitter reveals information regarding the emitter performance and may be used to adapt the input power to achieve a target value of the temperature. This may result in a constant IR emission. This embodiment and all other embodiments using a normal or an ordinary measurement signal, which may be also used to perform a gas concentration measurement of the PAS sensor, may be performed during normal operation of the photoacoustic sensor or during a separate calibration measurement.
According to further embodiments, a measurement signal of an acoustic sensor element of the photoacoustic sensor depends on an excitation frequency of the IR emitter. A change of the excitation frequency or an error of the IR emitter may be obtained by comparing the measurement signal to a stored reference signal. According to further embodiments, a transient behavior as well as an absolute value of a measurement signal of the gas concentration depends on or is based on a pressure of a reference cell. Comparing this transient behavior or performance, for example, with a stored performance, for example stored in an EEPROM or a further storage medium, may indicate a change of a pressure in the reference cell. This may provide information for a calibration or an error detection within the pressure measurement module or the reference cell.
According to further embodiments a variation of the temperature of the IR emitter results in a change of an emitted IR spectrum or a shift or offset of the spectrum. Therefore, by changing the emitter temperature a sensitivity of the photoacoustic sensor may be achieved for different gases, which may result in an adjustable sensitivity of the PAS sensor. A regular (periodic) comparison with a stored behavior reveals information about a composition of a current measurement gas, for example in a long-term measurement, or reveals information of a change of the sensor characteristics or an error in the PAS sensor, for example when evaluating a short-term profile.
According to further embodiments, a transient behavior and an achieved temperature of the emitter depends on a composition of the surrounding gases, for example of a (atmospheric) humidity. Periodically comparing the measured transient behavior to a stored transient behavior reveals information of a composition of the gases, for example sealing gases of the IR emitter and/or the acoustic sensor element of the photoacoustic sensor, if, for example, evaluating a long-term behavior. Moreover, it may reveal information about a change of the properties or characteristics of the photoacoustic sensor if for example evaluating a short-term behavior. A change of, for example a sealing gas of the IR emitter may influence the heating performance of the IR emitter. It may be seen that for example a humidity or a composition of gases may change comparably slow, which may be measured or detected in a long-term measurement or long-term behavior, wherein a degradation of the emitter may be comparably fast or even performed by a jump-up or by a sharp rise, which may be measured in a short-term behavior or short-term measurement of the photoacoustic sensor.
Embodiments relate to an in-use, online, or in-situ calibration of PAS-sensors comprising error detection or detection of cross-sensitivities, for example by a change of a sealing gas composition, which affects the measurement or detection of gas concentrations of a measurement gas. Therefore, a temperature sensor may measure an IR emitter temperature and compare the measured temperature to a target value or a stored value with respect to (or considering) an input power to the IR emitter. The temperature sensor may be, for example, a PT wire which may be used both as the IR emitter (or heater) and the temperature sensor. This may relate to both, a typical AC or DC behavior or a transient behavior. Moreover, a transient behavior of a gas sensor measurement unit (i.e. the acoustic sensor element) of the photoacoustic sensor may be obtained and, for example, compared with a stored behavior. This may be achieved by a variation of the IR radiation by changing the input power to the IR emitter, analyzing the resulting measurement signal and comparing characteristic absorption curves of different gases. This may be achieved using for example the upcoming embodiments of the third aspect.
To be more specific, according to embodiments an in-situ or in use calibration of the photoacoustic sensor 4 may be performed based on the calibration information 20 which may be derived from a physical parameter or characteristic of the photoacoustic sensor or, for example, of the IR emitter 6 of the photoacoustic sensor, and which are achieved or detected during operation of the photoacoustic sensor or the IR emitter, respectively.
The sensing unit may be configured to detect or measure the physical characteristic of the IR emitter and to provide the calibration unit with measurement signals (or an information signal) based on the detected physical characteristic. The sensing unit may be part of the photoacoustic sensor for directly sensing the physical parameter or, alternatively, may be arranged external to the photoacoustic sensor for indirectly sensing the physical parameter.
The in-situ calibration of the photoacoustic sensor may be conducted by adjusting the IR emitter based on the calibration information, e.g. by adjusting a control signal fed to the IR emitter and/or by correcting the output signal of the IR emitter (or a signal derived from the output signal). Moreover, the in-situ calibration of a photoacoustic sensor may be conducted during processing or evaluating the output signal of the IR emitter (or a signal derived from the output signal), wherein the detected calibration information is incorporated into the processing or evaluating of the output signal of the IR emitter (or a signal derived from the output signal). As a result, a corrected processing or evaluating of the output signal of the IR emitter (or a signal derived from the output signal) can be conducted. Therefore, a calibrated measurement signal may be achieved.
In the following, some exemplary calibration concepts are described in the context of the embodiments of
An acoustic sensor (element) of the photoacoustic sensor may receive an acoustic signal from a measurement gas, which may be excited by an (alternating or modulated) electromagnetic spectrum or signal. The calibration unit performs an iteration or analysis of the measurement signals 22 and compares the measurement signals to each other. Optionally, the calibration unit 10 compares the measurement signals to a stored reference if, for example the current reference gas composition is known. These may be options to derive the calibration information. However according to a preferred embodiment, the calibration unit may adjust the input of the IR emitter based on the calibration information such that a target IR radiation or temperature of the IR emitter is obtained if the calibration information reveals that a current performance of the IR emitter changed compared to an initial calibration or a previous calibration.
Additionally or alternatively, to adjust the input power of the IR emitter, it may be further changed a mapping or a transformation of the measurement signal to a respective gas concentration in the measurement gas, for example by adjusting a lookup table based on the calibration information. In other words, the calibration unit 10 may be configured to calibrate a determination of gas concentration in the photoacoustic sensor using the calibration information to perform the in-situ calibration. The determination of the gas concentration may be based on a further measurement signal of the photoacoustic sensor. The further measurement signal may be derived using settings of the IR emitter that are different from the settings applied for measuring the (first or previous) measurement signal. A different setting may refer to different temperatures, different IR radiation or in general, electromagnetic radiation, e.g. induced by a change of the electrical current, voltage, or input power.
In other words, the calibration unit 10 may be configured to calculate a current ratio of a first of the at least two measurement signals and a second of the at least two measurement signals, wherein the calibration unit is further configured to compare the current ratio to a target ratio. However, the first and the second of the at least two measurement signals may be derived using settings of the IR emitter for the first of the at least two measurement signals that are different from the settings applied for measuring the second of the at least two measurement signals.
According to further embodiments, the apparatus 2″ may optionally comprise a processing unit 15, which may be configured to adjust the electric power such that an absolute difference of the current ratio to the target ratio is reduced, or the calibration unit may be configured to calibrate a determination of a gas concentration in the photoacoustic sensor such that the absolute difference of the current ratio to the target ratio is reduced.
In other words, a drift of the spectrum, e.g. due to a change of the emissivity of the emitter, may be applied or forced and further calibrated through a change of the temperature of the emitter. Therefore, having a current operating point that is slowly or even not changing or drifting, e.g. the operating point being sensitive to an absorption spectrum of a slowly or even not changing gas (composition), a comparison of one or more operating points may indicate a degradation or even an amount of degradation of the IR emitter. An operating point is e.g. measurement using a current temperature or IR radiation of the IR emitter.
Moreover, the processing unit may be configured to process an output signal 17 of the photoacoustic sensor based on the calibration information to obtain an adjusted output signal of the photoacoustic sensor. The output signal of the photoacoustic sensor may be a response of an acoustic sensor element of the photoacoustic sensor to the IR radiation of the IR emitter or a gas concentration of a gas component of the measurement gas or a composition of the measurement gas. However, the calibration information may be provided to the IR emitter or to the processing unit or to both, the IR emitter and the processing unit. In other words, a direct adjustment of the IR emitter may perform an adjustment of the IR radiation of the IR emitter, wherein an indirect adjustment may calculate a calibration value based on e.g. a deviation of the (current) IR radiation (measure) to a calibrated IR radiation (measure), e.g. using a lookup table, to adjust the output signal of the photoacoustic sensor. Moreover, the processing unit 15 and the calibration unit 10 may be implemented in the same or a common (micro-) processor.
The in-situ calibration of the photoacoustic sensor may be conducted by adjusting the IR emitter based on the calibration information, e.g. by adjusting a control signal fed to the IR emitter and/or by correcting the output signal of the IR emitter (or a signal derived from the output signal). Moreover, the in-situ calibration of a photoacoustic sensor may be conducted during processing or evaluating the output signal of the IR emitter (or a signal derived from the output signal), wherein the detected calibration information is incorporated into the processing or evaluating of the output signal of the IR emitter (or a signal derived from the output signal). As a result, a corrected processing or evaluating of the output signal of the IR emitter (or a signal derived from the output signal) can be conducted.
More specifically, a first of the at least two measurement signals may be derived using a spectrum, which is sensitive to the current measurement gas. As a reference, a second measurement signal of the at least two measurement signals may be obtained using a spectrum, which is not sensitive to the current measurement gas. A difference of the second measurement signal (reference measure) to a reference measure obtained during calibration of the photoacoustic sensor may result in the calibration information, which may be applied to the first measurement signal. For example, the first measurement signal may be increased or decreased by the difference obtained from the reference measure. In other words, the calibration information is the difference obtained from the reference measure or a measure of the difference obtained from the reference measure.
Furthermore, an intensity of the IR radiation of the IR emitter may be derived from an alternating sequence of the at least two measurement signals, obtained from an alternating sequence of two electromagnetic spectra (e.g. IR spectra). The two electromagnetic spectra may be chopped or iteratively alternated using a (chopping) frequency which may be (e.g. at least 10 times) higher than a (average) change of the composition of the measurement gas. In other words, from two different sensitivities of the acoustic sensor element of the photoacoustic sensor, related to two different electromagnetic spectra, the (current) intensity of the IR emitter may be derived.
Since the whole photoacoustic sensor 4 may be implemented in one or more semiconductor substrates, it may be advantageous to also include the apparatus 2, 2′, or 2″ (which are mutually applicable) in one of the semiconductor substrates used to form the photoacoustic sensor. This may reduce a construction size of the overall microelectromechanical system 100. It is further advantageous to integrate the apparatus into the photoacoustic sensor, since the measurement device or the sensing unit 8, 8′ may be easily formed within the semiconductor substrate, for example using a pn junction, a thermopile or a (temperature depending) resistor. In other words, the micromechanical system 100 may comprise an apparatus and the IR emitter, wherein the apparatus and the IR emitter of the photoacoustic sensor are formed in a common semiconductor substrate, and wherein the sensing unit or sensing element 8′ or measurement device 8 comprises a semiconductor sensing unit formed within the semiconductor substrate. A semiconductor sensing unit may be a semiconductor temperature sensing unit or a semiconductor IR sensing unit. In other words, the semiconductor sensing unit may be formed or integrated in the semiconductor substrate. However, the description regarding the sensing units also applies mutatis mutantis or analogously.
Moreover, the described photoacoustic sensor 4 comprising a wafer stack of multiple wafers 102 may use or provide a chopper or modulation frequency within 1 to 100 Hz and a comparably small heat or thermal capacity. The modulation of the IR emitter may be performed using a change of an amplitude of the input signal or a change of the frequency of the input signal of the IR emitter. Therefore, the IR emitter may be operated using pulse-width modulation, amplitude modulation, or pulse-density modulation.
Moreover, an integrated apparatus 2, 2′, 2″, wherein the apparatus and the photoacoustic sensor are integrated in one or more common semiconductor substrates to form a microelectromechanical system. Such a microelectromechanical system are small systems having and enabling high duty cycles due to a low heat or thermal capacity. Moreover, multigas sensors may be formed e.g. by forming an array of these microelectromechanical systems having different (IR) excitation frequencies, or using different (IR) excitation frequencies in one microelectromechanical system, e.g. one after the other. Again, the small heat capacity resulting in a fast cool down of the IR emitter enables the system driving different excitation frequencies in a rapid succession.
In the following, multiple methods will be described which may be performed by one or more of the previously described aspects.
During operation of the IR emitter 6, in a step 710 a transient behavior of the power/resistor is measured. Accordingly, a transient behavior of the power/resistor is derived from the calibrated temperature dependency based on the current power input of the IR emitter in a step 715. In a step 720, the transient behavior of the power/resistor of the measurement and the calibrated value is compared. Furthermore, in a step 725, an adapted (input) power of the IR emitter or an adapted form of the input signal to the IR emitter 6 is calculated to keep the temperature/form on target, wherein in a step 730 the calculated power or form of the input signal is applied to the IR emitter 6. The method 700 may perform a control or calibration of the IR emitter based on a transient behavior.
The apparatus 2′ for in-situ calibration of a photoacoustic sensor 4 comprises a light emitter 6, an acoustic sensor element 112, a sensing unit 8a and a calibration unit 10. The light emitter may emit light along a transmission path 210 to a gas which may be a measurement gas. The acoustic sensor element 112 may detect an acoustic signal emitted from the gas based on the received light. In other words, the acoustic signal, also referred to as photoacoustic signal, is caused by the emitted light that affects the gas. The sensing unit 8a may detect the light transmitted along the transmission path 6 and provides an output signal. The calibration unit receives the output signal from the sensing unit 8a and provides a calibration information based on the output signal from the sensing unit 8a. The calibration information may be used to in-situ calibrate the photoacoustic sensor.
The photoacoustic sensor may comprise sensing units 8a, 8b, 8c, 8d in the regular light transmission path used to determine physical characteristics of the IR emitter or the acoustic sensor element 112 of the photoacoustic sensor. The resulting output signals of the sensing units may be used to determine a difference between an expected physical characteristics determined using a calibrated photoacoustic sensor and the current physical characteristics. Thus, based on the difference, the photoacoustic sensor may be in-situ (e.g. during regular operation of the photoacoustic sensor without affecting the operation) recalibrated, e.g. by minimizing the difference due to adjusting the IR emitter and/or adapting an output signal of the photoacoustic sensor.
In other words, the apparatus 2′, 2″ comprises a calibration unit 10 configured to control a signal generator 12 (not shown in
According to embodiments, the calibration unit 10 may control the signal generator 12 such that the signal generator feeds the IR emitter with an electric pulse as the electric signal. In other words, the electric signal formed by the signal generator may be an electric pulse. To form the electric pulse, the apparatus 2′, 2″ may comprise a further optional sensing unit 8d configured to detect the current physical characteristic of the IR emitter 6, wherein the calibration unit comprises a threshold switch configured to signal the signal generator to stop feeding the IR emitter with the electric signal if the physical characteristic exceeds a threshold value. The physical characteristic describes e.g. an inbound radiation or (an emission spectrum of) light or a corresponding temperature that may be determined based on the detected light spectrum.
Therefore, the further sensing unit 8d may be located in close proximity, e.g. located in the same chamber as the IR emitter. A distance 204c between the further sensing unit 8d and the IR emitter 6 may be less than 0.5 times, less than 0.25 times, or less than 0.1 times a distance between the IR emitter 6 and the acoustic sensor element 112. The close proximity of the further sensing unit 8d to the IR emitter enables measuring the physical characteristic of the IR emitter with high precision.
Furthermore, the threshold switch may comprise a hysteresis such that, when falling behind a further threshold value, the signal generator starts feeding the IR emitter with the electric signal. In other words, the threshold switch may be (electrically) connected to the further sensing unit 8d, which may be a photodiode or a temperature sensor. If the (predetermined) threshold of a brightness or temperature of the IR emitter is reached, the IR emitter may be stopped heating. The regular measurement and/or the calibration measurement may therefore be performed using a constant emitted power or constant emitted spectrum of the IR emitter. According to one embodiment, the photoacoustic sensor may be operated in a pulse mode. In the pulse mode, the IR emitter is controlled such that the emitted intensity increases until a maximum value is reached and thereafter decreases until a minimum value is reached. Even when the photoacoustic sensor is operated in a pulse mode, the threshold switch allows to perform the calibration measurement at the same characteristic of the emitted light, e.g. same power or same frequency spectrum of the emitted light. To ensure that the same characteristic is used for the calibration, the calibration is triggered when the threshold switch reaches the threshold. The threshold switch may be a Schmitt-Trigger. However, additionally or instead of the further (lower) threshold value, a time-based restart of the heating of the IR emitter may be performed. Thus, the calibration unit may be configured to restart the heating of the IR emitter by applying the electric signal to the IR emitter.
The electric pulse may vary in terms of e.g. frequency spectrum of the light or IR radiation emitted by the IR emitter that may be caused due to providing a different input power to the IR emitter resulting in a different emitted spectrum for calibration and deterioration detection. E.g., if an input power of between 0.8 W and 1.2 W causes an emitted spectrum of a highest intensity between 5 μm and 7 μm, wherein a lower input power of between 0.3 W and 0.7 W may cause an emitted spectrum of a highest intensity between 2 μm and 4 μm.
Furthermore, using different signal pulses having different characteristics may enable differentiating between effects caused by changes of the characteristics within the measurement gas that may vary due to varying pressures, compositions or temperatures of the measurement gas, and influences which are not caused by the measurement gas such as effects due to the reference gas outside the measuring chamber or any polluted or degraded component. The different characteristics may for example include different repetition frequencies of the emitted light pulses (e.g. 10 Hz and 100 Hz repetition frequency), different emitted spectra of the emitted light pulses or different shapes of the emitted light pulses. Without any influence on the emitted IR spectrum of the IR emitter outside the measuring chamber, the photoacoustic signal generated by the emitted IR spectrum shows a known dependency on frequency and/or amplitude changes of the emitted IR signal. Thus, if the dependency between two different pulses differs from an expected dependency, e.g. if the dependency is non-linear rather than expected linear, it may be an indication that the photoacoustic sensor suffers e.g. from degradation and should be recalibrated. Using this technique, it is possible to even perform the in-situ calibration during regular measurements. Moreover, the frequency response of the acoustic sensor element 112 may be determined using different pulses of varying frequencies of the emitted IR spectrum. These pulses may be used for measuring as measuring pulses and/or for calibration as calibration pulses. Measurement signals or pulses may be referred to as primary signals wherein calibration signals or pulses may be referred to as secondary signals. Thus, according to embodiments, secondary signals may have the same characteristics and may be the same signals as the primary signals. In other embodiments, secondary signals may have different characteristics as primary signals.
According to embodiments, the at least one of the sensing units 8a, 8b, 8c, 8d may be dedicated to specific properties. For example, the sensing units 8a, 8b, 8c, 8d may be sensitive to a specific frequency or frequency range of the emitted IR or light spectrum. If any of the sensing units, when referring
According to embodiments, the sensing unit 8a is located at a first distance 204a to an acoustic sensor element 112 of the photoacoustic sensor and at a second distance 204b to the IR or light emitter 6 of the photoacoustic sensor, wherein the first distance is smaller than the second distance. In other words, the sensing unit 8a is located at a spatial position close to gas receiving the emitted light and converting to the emitted light to an acoustic signal The IR light reaching the sensing unit and the IR light reaching the gas are then both attenuated by substantially the same amount when compared to the physical characteristic at the IR emitter. An acoustic sensor element 112 for measuring the acoustic signal is arranged within the gas. In further other words, the sensing unit 8a may be located at a spatial position with respect to the acoustic sensor element 112 of the photoacoustic sensor such that the acoustic sensor element 112 and the sensing unit 8 share substantially the same effective transmission path of the emitted IR light.
In some embodiments, the acoustic sensor element 112 may be located in a reference chamber 110. In such embodiments, the acoustic sensor element 112 and the chamber in which the sensing unit 8 is located may share substantially the same effective transmission path of the emitted IR light. By having the same effective transmission path of the emitted IR light, the sensing unit 8 is capable of measuring influences throughout the complete light transmission path used for the regular operation of the photoacoustic sensor. In embodiments, the length of both effective transmission paths may differ by not more than 5%, in other embodiments by not more than 10% and in still other embodiments by not more than 20%. The transmission path may be referred to as the shortest straight connection between the light emitter and the acoustic sensor element. Thus, refractions or optical shields affecting the transmitted light may be omitted.
In order to obtain the same effective transmission path, the sensing unit 8a is arranged in close proximity to the acoustic sensor element 112. This location of the sensing unit 8a in close proximity to the acoustic sensor element (microphone) 112 enables detecting multiple possible errors, changes, or alterations of the photoacoustic sensor which may occur in the transmission path, e.g. displacement of components within the transmission path, degradations of chamber windows or other optical elements due to dust or other particles etc. Distinguished from other concepts which monitor only the emitter or test only the acoustic sensor element 112, the described embodiments enable detecting degradation of all relevant components and takes them into account for calibration. The concept achieves this in a simple manner which requires only one sensing unit 8a at the end of the operative regular transmission path. However, optionally more than one sensing unit may be used.
According to some embodiments, the inner surfaces of the reference chamber 110 in which the acoustic sensor element 112 is placed may be coated with a reflecting material such as e.g. a gold coating. The reflecting coating enables reflections of the emitted light within the reference chamber 110 thus increasing the effective optical path of the signal emitted by the IR emitter. When using for example a pure reference gas in the reference chamber 110, this reference gas may serve as a natural filter where an increased effective optical path increases the effectivity of the filtering capabilities of the reference gas. Typically, photoacoustic sensors measure the purity of a measurement gas or a measurement gas composition. Thus a pure, i.e. an uncontaminated portion of the measurement gas or the measurement gas composition may be enclosed in the reference chamber surrounding the acoustic sensor element 112. Optical filters may be omitted.
Generally, the goal of calibrating the photoacoustic sensor is to control the stability or reliability of the photoacoustic sensor with all components. Hence, it is possible to detect changes within the complete transmission path or measurement path between the IR emitter and the acoustic sensor element 112 of the photoacoustic sensor. Changes or errors may be a degradation of the IR emitter, the surface of the IR emitter or (transparent) windows or transparent sealing 108a, 108b in the transmission path of the photoacoustic sensor element or misalignments of components. Furthermore, the windows may be polluted e.g. by dust, particles or due to condensation. Additionally, the photoacoustic sensor may be mechanically corrupted if e.g. a relative position of the IR emitter to the acoustic sensor element 112 is changed which may be caused by shocks during installation.
According to further embodiments, the apparatus 2′, 2″ comprises a further sensing unit 8d configured to detect the current physical characteristic of the IR emitter 6 at a position different from the position of the sensing unit. The further sensing unit 8d is located in a spatial position that is closer to the IR emitter when compared to a spatial position of the sensing unit 8a. In other words, the further sensing unit is located at a third distance 204c to the IR emitter, wherein the third distance is smaller than the second distance 204b. Furthermore, the embodiment is not limited to one further sensing unit. In some embodiments more than one further sensing units, such as sensing units 8c and 8d, may be placed at different positions in the photoacoustic sensor or nearby the photoacoustic sensor. The further sensing units 8c, 8d may be used to narrow a location or to locate the actual position of an error within the photoacoustic sensor. Thus, the sensing units may be located, in the view from the IR emitter, behind a respective component which may suffer from degradation or other changes during the lifecycle of the photoacoustic sensor. Thus, the further sensing units determine the physical characteristics of the IR light which is only partially attenuated (compared to the attenuation at the end of the transmission path) since the further sensing units are located between the sensing unit 8a and the IR emitter. Depending on the attenuation at the further sensing units, the deteriorated component of the photoacoustic sensor may be identified and compensated for. The amount of attenuation may be measured to directly estimate an amount of recalibration. The amount of recalibration may refer to a greater power of the electric signal or the electric pulse applied to the IR emitter and/or a degree of adaption of the output signal of the photoacoustic sensor. The adaption of the output signal enables to adjust the output signal such that the undesired attenuation is compensated.
According to embodiments, the calibration unit 10 is configured to determine which signal or signals should be adapted for calibration, based on a difference of the physical characteristic measured by the sensing unit 8a and the physical characteristic measured by the further sensing unit 8b, 8c, 8d. To be more specific, it can be determined whether to apply the calibration information for adjusting the IR emitter or to apply the calibration information to an output signal of the photoacoustic sensor for correcting the output signal. In other words, if the further sensing units identify the IR emitter as being suffering from degradation, the power of the electric signal may be readjusted to achieve a constant (maximum) brightness or temperature. However, if e.g. the windows are polluted, the output signal may be adjusted to avoid an adaption of the IR emitter resulting in higher temperatures and increased degradation or to avoid a change of the emitted (light) spectrum of the IR emitter.
In the described embodiments, the apparatus 2′, 2″, when performing the in-situ calibration, may use only signals from the same transmission path that are used to perform a regular measurement on a measurement gas. In other words, external signals are absent, such as e.g. signals from an acoustic generator for testing the acoustic sensor element. Therefore, the calibration information may be derived only from the physical characteristic of the IR emitter.
Moreover, above have been described the sensing units 8a and 8d.
Thus, the further sensing unit 8c may detect the emitted light through a transmission path having a direction 212 different from a direction 210 of the transmission path. Thus, when referring to
Further embodiments relate to the following examples:
1. Apparatus 2 for in-situ calibration of a photoacoustic sensor 4, the apparatus comprising: a measurement device 8 configured to measure a current electric signal 18 at the IR emitter 6 of the photoacoustic sensor 4; a calibration unit 10 configured to compare the current electric signal 18 at the IR emitter with a comparison value for the electric signal to achieve a comparison result forming a calibration information; wherein, when performing the in-situ calibration, the calibration information is applicable to the photoacoustic sensor for adjusting the IR emitter and/or is applicable to an output signal of the photoacoustic sensor for correcting the output signal.
2. Apparatus 2 according to example 1, wherein the calibration unit 10 is configured to adjust the current electric signal based on the comparison result to obtain a target value of the electric signal at the IR emitter to perform the in-situ calibration.
3. Apparatus 2 according to example 1 or 2, further comprising: a processing unit 15 configured to process the output signal of the photoacoustic sensor based on the calibration information to obtain an adjusted output signal of the photoacoustic sensor.
4. Apparatus 2 according to any of examples 1 to 3, wherein the calibration unit is configured to adjust the target value of the electric signal such that a target value of a physical characteristic of the IR emitter 6 is obtained.
5. Apparatus 2 according to any of examples 1 to 4, wherein the calibration unit 10 is configured to adjust the current electric signal 18 such that a change of resistance of the IR emitter is compensated.
6. Apparatus 2 according to any of examples 1 to 5, wherein the current electric signal 18 comprises an electric pulse and wherein the calibration unit 10 is configured to calculate a time constant of the photoacoustic sensor 4 from a current physical characteristic based on the electric pulse, wherein the time constant indicates an ability of the current physical characteristic to follow the electric pulse.
7. Apparatus according to any of examples 1 to 6, wherein the current electric signal 18 comprises an electric pulse and wherein the calibration unit 10 is configured to adjust the electric pulse such that at least one of an edge steepness, an amplitude, or a repetition frequency of the electric pulse is changed; wherein the change of the electric pulse changes the physical characteristic of the IR emitter such that the absolute difference between a current physical characteristic and the target value of the physical characteristic is reduced.
8. Apparatus 2 according to any of examples 1 to 7, wherein the current electric signal comprises an electric pulse and wherein a current physical characteristic is different from the target value of the physical characteristic due to a degradation of the IR emitter 6 and wherein the calibration unit 10 is configured to adjust a current electric signal or the electric pulse such that the degradation of the IR emitter is compensated.
9. Apparatus (2′) for in-situ calibration of a photoacoustic sensor (4), the apparatus (2) comprising: a calibration unit (10) configured to control a signal generator (12) such that the signal generator feeds the IR emitter with an electric pulse; a sensing unit (8′) configured to detect a current physical characteristic of a surface of the IR emitter (6), wherein the current physical characteristic of the IR emitter depends on the electric pulse; wherein the calibration unit is configured to compare the current physical characteristic of the surface of the IR emitter (6) with a target value of the physical characteristic of the surface of the IR emitter to obtain a calibration signal (11′) forming a calibration information, wherein, when performing the in-situ calibration, the calibration information is applicable to the signal generator (12) for adjusting the IR emitter and/or is applicable to an output signal of the photoacoustic sensor for correcting the output signal.
10. Apparatus (2′) according to example 9, wherein the calibration unit (10) is configured to adjust the electric pulse of the signal generator (12) based on the calibration information to perform the in-situ calibration.
11. Apparatus (2′) according to example 9 or 10, further comprising: a processing unit (15) configured to process an output signal of the photoacoustic sensor based on the calibration information to obtain an adjusted output signal of the photoacoustic sensor.
12. Apparatus (2′) according to any of examples 9 to 11, wherein the sensing unit is configured to measure a temperature of the surface of the IR emitter (6) using determining a temperature of an environment of the IR emitter; or wherein the sensing unit (8′) is configured to measure an infrared radiation of the IR emitter (6) at the surface of the IR emitter.
13. Apparatus (2′) according to any of examples 9 to 12, wherein the apparatus (2′) comprises the signal generator (12), wherein the signal generator is configured to generate the electric pulse and to feed the IR emitter (6) of the photoacoustic sensor (4) with the electric pulse.
14. Apparatus (2′) according to any of examples 9 to 13, wherein the calibration unit is configured to calculate a time constant of the photoacoustic sensor (4) from the current physical characteristic based on the electric pulse, wherein the time constant indicates an ability of a current physical characteristic to follow the electric pulse.
15. Apparatus (2′) according to any of examples 9 to 14, wherein the calibration unit is configured to adjust the electric pulse such that at least one of an edge steepness, an amplitude, or a repetition frequency of the electric pulse is changed; wherein the change of the electric pulse changes the physical characteristic of the IR emitter (6) such that the absolute difference between the current physical characteristic and the target value of the physical characteristic is reduced.
16. Apparatus (2′) according to any of examples 9 to 15, wherein the current physical characteristic is different from the target value of the physical characteristic due to a degradation of the IR emitter and wherein the calibration unit is configured to adjust the electric pulse such that the degradation of the IR emitter (6) is compensated.
17. Microelectromechanical system (100) comprising: an apparatus (2′) according to any of examples 9 to 16, wherein the apparatus and the IR emitter of the photoacoustic sensor are formed in a common semiconductor substrate; wherein the sensing unit (8′) comprises a semiconductor sensing unit formed within the semiconductor substrate.
18. Apparatus or microelectromechanical system according to any of examples 1 to 17, wherein the physical characteristic comprises a temperature or an emissivity or a radiation of an electromagnetic signal of the IR emitter.
19. Use of an apparatus according to any of examples 1 to 16 or the microelectromechanical system according to example 17 to perform a method described herein.
It is to be understood that in this specification, the signals on lines are sometimes named by the reference numerals for the lines or are sometimes indicated by the reference numerals themselves, which have been attributed to the lines. Therefore, the notation is such that a line having a certain signal is indicating the signal itself. A line can be a physical line in a hardwired implementation. In a computerized implementation, however, a physical line does not exist, but the signal represented by the line is transmitted from one calculation module to the other calculation module. Moreover, the lines may be understood to be unidirectional or bidirectional depending on the context of the embodiment. Hence, the (corresponding) signals may be understood to be unidirectional or bidirectional as well.
Although the present invention has been described in the context of block diagrams where the blocks represent actual or logical hardware components, the present invention can also be implemented by a computer-implemented method. In the latter case, the blocks represent corresponding method steps where these steps stand for the functionalities performed by corresponding logical or physical hardware blocks.
Although some aspects have been described in the context of an apparatus, it is clear that these aspects also represent a description of the corresponding method, where a block or device corresponds to a method step or a feature of a method step. Analogously, aspects described in the context of a method step also represent a description of a corresponding block or item or feature of a corresponding apparatus. Some or all of the method steps may be executed by (or using) a hardware apparatus, like for example, a microprocessor, a programmable computer or an electronic circuit. In some embodiments, some one or more of the most important method steps may be executed by such an apparatus.
The inventive transmitted or encoded signal can be stored on a digital storage medium or can be transmitted on a transmission medium such as a wireless transmission medium or a wired transmission medium such as the Internet.
Depending on certain implementation requirements, embodiments of the invention can be implemented in hardware or in software. The implementation can be performed using a digital storage medium, for example a floppy disc, a DVD, a Blu-Ray, a CD, a ROM, a PROM, and EPROM, an EEPROM or a FLASH memory, having electronically readable control signals stored thereon, which cooperate (or are capable of cooperating) with a programmable computer system such that the respective method is performed. Therefore, the digital storage medium may be computer readable.
Some embodiments according to the invention comprise a data carrier having electronically readable control signals, which are capable of cooperating with a programmable computer system, such that one of the methods described herein is performed.
Generally, embodiments of the present invention can be implemented as a computer program product with a program code, the program code being operative for performing one of the methods when the computer program product runs on a computer. The program code may, for example, be stored on a machine readable carrier.
Other embodiments comprise the computer program for performing one of the methods described herein, stored on a machine readable carrier.
In other words, an embodiment of the inventive method is, therefore, a computer program having a program code for performing one of the methods described herein, when the computer program runs on a computer.
A further embodiment of the inventive method is, therefore, a data carrier (or a non-transitory storage medium such as a digital storage medium, or a computer-readable medium) comprising, recorded thereon, the computer program for performing one of the methods described herein. The data carrier, the digital storage medium or the recorded medium are typically tangible and/or non-transitory.
A further embodiment of the invention method is, therefore, a data stream or a sequence of signals representing the computer program for performing one of the methods described herein. The data stream or the sequence of signals may, for example, be configured to be transferred via a data communication connection, for example, via the internet.
A further embodiment comprises a processing means, for example, a computer or a programmable logic device, configured to, or adapted to, perform one of the methods described herein.
A further embodiment comprises a computer having installed thereon the computer program for performing one of the methods described herein.
A further embodiment according to the invention comprises an apparatus or a system configured to transfer (for example, electronically or optically) a computer program for performing one of the methods described herein to a receiver. The receiver may, for example, be a computer, a mobile device, a memory device or the like. The apparatus or system may, for example, comprise a file server for transferring the computer program to the receiver.
In some embodiments, a programmable logic device (for example, a field programmable gate array) may be used to perform some or all of the functionalities of the methods described herein. In some embodiments, a field programmable gate array may cooperate with a microprocessor in order to perform one of the methods described herein. Generally, the methods are preferably performed by any hardware apparatus.
The above described embodiments are merely illustrative for the principles of the present invention. It is understood that modifications and variations of the arrangements and the details described herein will be apparent to others skilled in the art. It is the intent, therefore, to be limited only by the scope of the impending patent claims and not by the specific details presented by way of description and explanation of the embodiments herein.
Theuss, Horst, Jost, Franz, Kolb, Stefan, Dehe, Alfons, Huber, Jochen, Woellenstein, Juergen
Patent | Priority | Assignee | Title |
11610463, | May 18 2021 | Comcast Cable Communications, LLC | Sensor arrangement |
Patent | Priority | Assignee | Title |
10413193, | Oct 29 2009 | Canon Kabushiki Kaisha | Photoacoustic apparatus |
3694624, | |||
5394934, | Apr 15 1994 | MSA Technology, LLC; Mine Safety Appliances Company, LLC | Indoor air quality sensor and method |
7304732, | Nov 19 2003 | ARMY, UNITED STATES OF AMERICA REPRESENTED BY THE SECRETARY OF THE; UNTIED STATES OF AMERICA REPRESENTED BY THE SECREATARY OF THE ARMY | Microelectromechanical resonant photoacoustic cell |
8930145, | Jul 28 2010 | Covidien LP | Light focusing continuous wave photoacoustic spectroscopy and its applications to patient monitoring |
8939006, | May 04 2011 | Honeywell International Inc | Photoacoustic detector with long term drift compensation |
8970842, | Aug 15 2012 | The Trustees of Princeton University | Multi-harmonic inline reference cell for optical trace gas sensing |
20110106478, | |||
20120279279, | |||
20140049777, | |||
20150049168, | |||
20150092814, | |||
20150101395, | |||
CN102596049, | |||
WO2008072167, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Sep 03 2016 | WOELLENSTEIN, JUERGEN | Infineon Technologies AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 051151 | /0105 | |
Sep 05 2016 | KOLB, STEFAN | Infineon Technologies AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 051151 | /0105 | |
Sep 05 2016 | JOST, FRANZ | Infineon Technologies AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 051151 | /0105 | |
Sep 07 2016 | DEHE, ALFONS | Infineon Technologies AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 051151 | /0105 | |
Sep 09 2016 | HUBER, JOCHEN | Infineon Technologies AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 051151 | /0105 | |
Sep 19 2016 | THEUSS, HORST | Infineon Technologies AG | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 051151 | /0105 | |
Dec 02 2019 | Infineon Technologies AG | (assignment on the face of the patent) | / |
Date | Maintenance Fee Events |
Dec 02 2019 | BIG: Entity status set to Undiscounted (note the period is included in the code). |
Date | Maintenance Schedule |
Mar 15 2025 | 4 years fee payment window open |
Sep 15 2025 | 6 months grace period start (w surcharge) |
Mar 15 2026 | patent expiry (for year 4) |
Mar 15 2028 | 2 years to revive unintentionally abandoned end. (for year 4) |
Mar 15 2029 | 8 years fee payment window open |
Sep 15 2029 | 6 months grace period start (w surcharge) |
Mar 15 2030 | patent expiry (for year 8) |
Mar 15 2032 | 2 years to revive unintentionally abandoned end. (for year 8) |
Mar 15 2033 | 12 years fee payment window open |
Sep 15 2033 | 6 months grace period start (w surcharge) |
Mar 15 2034 | patent expiry (for year 12) |
Mar 15 2036 | 2 years to revive unintentionally abandoned end. (for year 12) |